Monolithic attitude control motor frame and system

ABSTRACT

A monolithic attitude control motor frame includes a monolithic structure including an outer surface of revolution and a plurality of side walls defining a plurality of cavities extending radially from the outer surface of revolution. Adjacent cavities of the plurality of cavities share a side wall or side wall portion therebetween. Each of the cavities is configured to receive an attitude control motor. A monolithic attitude control motor system includes a monolithic frame including an outer surface of revolution and a plurality of side walls defining a plurality of cavities extending radially from the outer surface of revolution. The system further includes a plurality of attitude control motors corresponding to the plurality of cavities, such that an attitude control motor of the plurality of attitude control motors is disposed in each cavity of the plurality of cavities.

TECHNICAL FIELD

The present invention relates in general to the field of vehicleattitude control.

DESCRIPTION OF THE PRIOR ART

Many modern vehicles require thruster control during certain phases offlight. Conventionally, such vehicles utilize solid gas generators orattitude control motors to achieve thruster control. These controldevices can be placed on the fore or aft ends for control momentapplications or generally in the center of the body for direct forcecontrol. Generally, solid gas generators use a larger grain volume and avalve system to direct the thrust in the desired direction. While thesesystems are able to package more impulse in a given volume, the massflow must remain fairly constant so that venting is required to preventoverpressurization, which wastes much of the desired packagedpropellant. Systems employing solid gas generators are also expensivedue to the valve and actuation systems required. Jet interaction is fanshaped in such systems and is, therefore, more complicated. Conventionalattitude control motor systems employ banks of individual,self-contained attitude control motors that are fired in the desireddirection to achieve forward thruster control. Conventional attitudecontrol motors are generally circular in cross-section to efficientlycontain pressurization forces when the motor is operated. Suchconventional motors, however, are bulky, self-contained pressure vesselswhen compared to their thrust output; that is, the motors require asignificant volume of the vehicle when compared to their thrust output.Some vehicles, therefore, cannot employ conventional attitude controlmotors, as insufficient volume exists in the vehicle.

While there are attitude control motor systems well known in the art,considerable room for improvement remains.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features believed characteristic of the invention are setforth in the appended claims. However, the invention itself, as well asa preferred mode of use, and further objectives and advantages thereof,will best be understood by reference to the following detaileddescription when read in conjunction with the accompanying drawings, inwhich the leftmost significant digit(s) in the reference numeralsdenote(s) the first figure in which the respective reference numeralsappear, wherein:

FIG. 1 is a perspective view of a first illustrative embodiment of amonolithic attitude control motor system;

FIG. 2 is an enlarged, perspective view of a portion of the monolithicattitude control motor system of FIG. 1 , as indicated in FIG. 1 , inwhich some of the attitude control motors are removed to better revealparticular aspects of a monolithic attitude control motor frame;

FIG. 3 is a cross-sectional view of a portion of the monolithic attitudecontrol motor frame, taken along the line 3-3 in FIG. 2 ;

FIG. 4 is a flattened graphical representation of the attitude controlmotor pattern of the monolithic attitude control motor system of FIG. 1;

FIGS. 5 and 6 are flattened graphical representations of exemplaryattitude control motor patterns alternative to that of FIG. 4 ;

FIG. 7 is an illustrative embodiment of an air- or water-travelingvehicle incorporating the monolithic attitude control system; and

FIG. 8 is an illustrative embodiment of an exoatmospheric vehicleincorporating the monolithic attitude control system.

While the invention is susceptible to various modifications andalternative forms, specific embodiments thereof have been shown by wayof example in the drawings and are herein described in detail. It shouldbe understood, however, that the description herein of specificembodiments is not intended to limit the invention to the particularforms disclosed, but on the contrary, the intention is to cover allmodifications, equivalents, and alternatives falling within the spiritand scope of the invention as defined by the appended claims.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Illustrative embodiments of the invention are described below. In theinterest of clarity, not all features of an actual implementation aredescribed in this specification. It will of course be appreciated thatin the development of any such actual embodiment, numerousimplementation-specific decisions must be made to achieve thedeveloper's specific goals, such as compliance with system-related andbusiness-related constraints, which will vary from one implementation toanother. Moreover, it will be appreciated that such a development effortmight be complex and time-consuming but would nevertheless be a routineundertaking for those of ordinary skill in the art having the benefit ofthis disclosure.

In the specification, reference may be made to the spatial relationshipsbetween various components and to the spatial orientation of variousaspects of components as the devices are depicted in the attacheddrawings. However, as will be recognized by those skilled in the artafter a complete reading of the present application, the devices,members, apparatuses, etc. described herein may be positioned in anydesired orientation. Thus, the use of terms such as “above,” “below,”“upper,” “lower,” or other like terms to describe a spatial relationshipbetween various components or to describe the spatial orientation ofaspects of such components should be understood to describe a relativerelationship between the components or a spatial orientation of aspectsof such components, respectively, as the device described herein may beoriented in any desired direction.

The present invention concerns a monolithic structure that utilizesshared pressure vessel walls of adjacent attitude control motors todistribute the operational pressure loads throughout the structure, thusallowing less structure as compared with self-contained pressurevessels.

The present invention relates to a monolithic attitude control motorframe that includes a monolithic structure comprising an outer surfaceof revolution and a plurality of side walls defining a plurality ofcavities extending radially from the outer surface of revolution.Adjacent cavities of the plurality of cavities share a side wall or sidewall portion therebetween. Each of the cavities is configured to receivean attitude control motor.

The present invention further relates to a monolithic attitude controlmotor system that includes a monolithic frame comprising an outersurface of revolution and a plurality of side walls defining a pluralityof cavities extending radially from the outer surface of revolution. Thesystem further includes a plurality of attitude control motorscorresponding to the plurality of cavities, such that an attitudecontrol motor of the plurality of attitude control motors is disposed ineach cavity of the plurality of cavities. Adjacent attitude controlmotors share a side wall or a portion of a side wall therebetween andwherein pressurization loads generated by operation of one of theplurality of attitude control motors are transmitted to the monolithicframe.

The present invention also relates to a vehicle that includes a body anda monolithic attitude control system operably associated with the body.The monolithic attitude control system includes a monolithic framecomprising an outer surface of revolution and a plurality of side wallsdefining a plurality of cavities extending radially from the outersurface of revolution. The system further includes a plurality ofattitude control motors corresponding to the plurality of cavities, suchthat an attitude control motor of the plurality of attitude controlmotors is disposed in each cavity of the plurality of cavities. Adjacentattitude control motors share a side wall or a portion of a side walltherebetween and pressurization loads generated by operation of one ofthe plurality of attitude control motors are transmitted to themonolithic frame.

The present system is particularly useful to provide thruster control tomany various types of vehicles, for example, air-traveling vehicles,such as aircraft, missiles, projectiles, rockets, air-travelingmunitions, and the like; water-traveling vehicles, such as torpedoes,submarine vehicles, water-traveling munitions, and the like;exoatmospheric vehicles, such as spacecraft, satellites, space-travelingmunitions, and the like.

FIG. 1 depicts a perspective view of a first illustrative embodiment ofa monolithic attitude control motor system 101. System 101 comprises amonolithic attitude control motor frame 103 housing a plurality ofattitude control motors, such as a plurality of attitude control motors105 and a plurality of attitude control motors 107. Note that only oneattitude control motor 105 and one attitude control motor 107 arelabeled in FIG. 1 for clarity, although a plurality of attitude controlmotors 105 and a plurality of attitude control motors 107 exist in theembodiment shown in FIG. 1 . It should be noted that, for the purposesof this disclosure, an “attitude control motor” is defined as apropellant-containing device configured to provide thrust but that omitsa pressure vessel for containing pressures induced by the operation ofthe propellant. Monolithic frame 103 acts as a pressure-containmentdevice, as discussed in greater detail herein. Illustrative examples ofattitude control motors 105 and 107 include, but are not limited to, aportion of propellant configured to be disposed in a cavity ofmonolithic frame 103, such as cavities 201 and 203 shown in FIGS. 2 and3 ; a portion of propellant disposed in a cup and configured to bedisposed in a cavity of monolithic frame 103; a portion of propellant,disposed in a cup or omitting a cup, operably associated with a nozzleand configured to be disposed in a cavity of monolithic frame 103, orthe like. It should be noted that the present invention contemplatesmany different configurations of attitude control motors for use in thepresent system.

Still referring to the embodiment illustrated in FIG. 1 , attitudecontrol motors 105 exhibit generally octagonal shapes proximate an outersurface 109 of monolithic frame 103 and attitude control motors 107exhibit generally rectangular or square shapes proximate outer surface109 of monolithic frame 103. It should be noted that outer surface 109is a surface of revolution about a centerline 111 of monolithic frame103. As is discussed in greater detail herein, the attitude controlmotors of the present system 101 exhibit shapes and/or dimensionsproximate outer surface 109 of monolithic frame 103 that allow theattitude control motors to be nested together, thus providing anefficient pack of attitude control motors.

Still referring to the embodiment of FIG. 1 , the plurality of attitudecontrol motors 105 and the plurality of attitude control motors 107 aredisposed generally radially about centerline 111 of monolithic frame 103such that, when operated, any of the attitude control motors generates athrust vector away from centerline 111, as indicated, for example, byarrows 113 and 115. As is discussed in greater detail herein, adjacentattitude control motors share common side walls or one or more portionsof side walls, such as a side wall 117, thus forming a honeycombstructure that allows pressurization loads generated by the operation ofone or more of the plurality of attitude control motors, such as one ormore of attitude control motors 105 and/or one or more of attitudecontrol motors 107, to be transmitted to monolithic frame 103. Thepresent invention contemplates any type of attitude control motors forattitude control motors 105 and 107, so long as they are configured toshare common side walls or one or more portions of side walls, i.e.,attitude control motors 105 and 107 provide generally no individualpressurization containment, as pressurization containment is provided bymonolithic frame 103. In certain embodiments monolithic frame 103defines a central passageway 119 for routing control lines to theplurality of attitude control motors 105 and the plurality of attitudecontrol motors 107, as well as other lines, devices, and the like asdesired. It should be noted, however, that the scope of the presentinvention encompasses embodiments wherein central passageway 119 or thelike is omitted, wherein control lines operatively associated with theplurality of attitude control motors 105 and the plurality of attitudecontrol motors 107 are routed by different pathways.

FIG. 2 depicts an enlarged, perspective view of a portion of monolithicattitude control motor system 101, as indicated in FIG. 1 , in whichsome of attitude control motors 105 and 107 are removed to better revealparticular aspects of monolithic frame 103. As shown in FIG. 2 ,monolithic frame 103 defines a plurality of cavities 201 correspondingto the plurality of attitude control motors 105 and defines a pluralityof cavities 203 corresponding to the plurality of attitude controlmotors 107. Note that in FIG. 2 only one cavity 201 and one cavity 203are labeled for clarity, although monolithic frame 103 defines a cavity201 in which each attitude control motor 105 is received and defines acavity 203 in which each attitude control motor 107 is received. In theillustrated embodiment, one or more of cavities 201 transitions andtapers from a generally octagonal or first polygon shape 205 at outersurface 109 to a generally rectangular or square or second polygon shape207 at an inner surface 121 (shown in FIGS. 1 and 3 ) of monolithicframe 103. Also, in the illustrated embodiment, one or more of cavities203 transitions and tapers from a generally rectangular or square shape209 at outer surface 109 to a generally rectangular or square shape 301(shown in FIG. 3 ) at inner surface 121 (shown in FIGS. 1 and 3 ). Itshould be noted, however, that the shapes and tapers of cavities 201 and203 shown in FIG. 2 are merely exemplary of the multitude of shapes andtapers of cavities contemplated by the present invention. Therefore,though non-limiting, the generally octagonal shape 205 may be considereda first geometric shape and where this shape tapers to a generallyrectangular or square shape 207 at the inner surface 121 may beconsidered a second geometric shape. Also, further non-limiting, thegenerally rectangular or square shape 209 at the outer surface 109 maybe considered a third geometric shape and the tapering to the generallyrectangular or square shape 301 at the inner surface may be consideredeither the third geometric shape or a fourth geometric shape. While FIG.2 depicts cavities 201 and 203 as having facets, the scope of thepresent invention is not so limited. Rather, interior surfaces ofcavities 201 and 203 are, in certain embodiments, three-dimensional,curved, i.e., non-planar, surfaces rather than faceted surfaces. Atleast some cavities includes first cavity side walls that taper towardthe centerline of the monolithic structure and second cavity side wallsthat taper toward the centerline of the monolithic structure. At leastone of the second cavity side walls have a facet or triangle shapebetween the outer surface of revolution and the inner surface of themonolithic structure to form at least one corner of the second polygon(i.e., square or rectangle). Each first cavity side wall has atrapezoidal shape between the outer surface of revolution and the innersurface of the monolithic structure. The first cavity side walls and thesecond cavity side walls can be in an alternating pattern. A secondcavity side wall is angled relative to adjacent first cavity side walls.

Referring to FIGS. 2 and 3 , and as discussed herein concerning FIG. 1 ,adjacent attitude control motors 105 and 107 share common side walls orone or more portions of side walls, which allows pressurization loadsgenerated by the operation of one of the plurality of attitude controlmotors, such as one of attitude control motors 105 or one of attitudecontrol motors 107, to be transmitted to monolithic frame 103. Such sidewalls define the plurality of cavities 201 and 203. For example, a sidewall 211 defines a portion of the particular cavity 201 labeled in FIG.2 as cavity 201 a and a portion of the particular cavity 203 labeled inFIG. 2 as cavity 203 a. Such side walls or portions of side walls in theaggregate form monolithic or unitary frame 103. Mechanicalpressurization loads generated by the operation of one or more of theplurality of attitude control motors, such as one or more of attitudecontrol motors 105 and/or one or more of attitude control motors 107,are transmitted to and resolved by monolithic frame 103.

The present invention contemplates many different arrangements, shapes,and sizes of attitude control motors in the monolithic attitude controlmotor system and, thus, contemplates many different arrangements,shapes, and sizes of cavities defined by the monolithic attitude controlmotor frame. FIG. 4 depicts a flattened graphical representation of theattitude control motor pattern 401 of the monolithic attitude controlmotor system of FIGS. 1-3 . In other words, the representation of FIG. 4depicts the pattern of the monolithic attitude control motor system ofFIGS. 1-3 as the pattern appears when “unrolled” from monolithicattitude control motor system 101 and flattened. As discussed herein,the illustrated pattern includes a plurality of attitude control motors105 that exhibit generally octagonal shapes at outer surface 109 ofmonolithic attitude control motor frame 103 and includes a plurality ofattitude control motors 107 that exhibit generally rectangular or squareshapes at outer surface 109. Thus, the illustrated pattern utilizes twosizes and shapes of attitude control motors in system 101.

FIGS. 5 and 6 depict flattened graphical representations of exemplaryattitude control motor patterns alternative to that shown in FIG. 4 . Inthe embodiment of FIG. 5 , a pattern 501 employs two sizes and shapes ofattitude control motors 503 and 505, as in the embodiment of FIG. 4 .Similarly to the embodiment of FIG. 4 , pattern 501 includes a pluralityof attitude control motors 503 that exhibit generally octagonal shapesat an outer surface of the monolithic attitude control motor frame(corresponding to outer surface 109 of monolithic attitude control motorframe 103) and includes a plurality of attitude control motors 505 thatexhibit generally rectangular or square shapes at the outer surface ofthe monolithic attitude control motor frame. The arrangement of attitudecontrol motors 503 and 505, however, is different from the arrangementof attitude control motors 105 and 107, shown in FIG. 4 . Attitudecontrol motors 503 and 505 are in a nested configuration to provide ahigh packing efficiency of attitude control motors.

In the embodiment of FIG. 6 , a pattern 601 employs a single size andshape for a plurality of attitude control motors 603. In pattern 601,each of the plurality of attitude control motors exhibits a generallyhexagonal shape at an outer surface of the monolithic attitude controlmotor frame (corresponding to outer surface 109 of monolithic attitudecontrol motor frame 103). As explained above, though not limiting, thegenerally hexagonal shape may be considered a first geometric shape and,as further explained above, this shape may taper to a second shape atthe inner surface 121. Attitude control motors 603 are in a nestedconfiguration to provide a high packing efficiency of attitude controlmotors.

As described herein, the present monolithic attitude control motorsystem, such as system 101, may be operatively associated with manyvarious types of vehicles for providing vehicle thrust control. FIGS. 7and 8 provide examples of two types of vehicles that incorporate thepresent monolithic attitude control motor system. It should be noted,however, that the present invention contemplates many different types ofvehicles that employ the present monolithic attitude control motorsystem. In the embodiment of FIG. 7 , an air- or water-traveling vehicle701 comprises a body 703, which is operatively associated with a firstmonolithic attitude control motor system 705 disposed proximate a foreend 707 of body 703 and a second monolithic attitude control motorsystem 709 disposed proximate an aft end 711 of body 703. In theembodiment of FIG. 8 , an exoatmospheric vehicle 801 comprises a body803 operatively associated with a monolithic attitude control motorsystem 805. In one implementation, monolithic attitude control motorsystem 805 is disposed proximate a center of mass of exoatmosphericvehicle 801.

The present invention provides significant advantages, including: (1)providing an attitude control motor system that exhibits higherpackaging efficiency than conventional attitude control motor systems;(2) providing an attitude control motor system that provides a largeamount of total impulse than conventional attitude control motorsystems; and (3) providing an attitude control motor system that betterresolves pressurization forces during operation of the attitude controlmotors.

The particular embodiments disclosed above are illustrative only, as theinvention may be modified and practiced in different but equivalentmanners apparent to those skilled in the art having the benefit of theteachings herein. Furthermore, no limitations are intended to thedetails of construction or design herein shown, other than as describedin the claims below. It is therefore evident that the particularembodiments disclosed above may be altered or modified and all suchvariations are considered within the scope and spirit of the invention.Accordingly, the protection sought herein is as set forth in the claimsbelow. It is apparent that an invention with significant advantages hasbeen described and illustrated. Although the present invention is shownin a limited number of forms, it is not limited to just these forms, butis amenable to various changes and modifications without departing fromthe spirit thereof.

The invention claimed is:
 1. A monolithic attitude control motor frame,comprising: a monolithic structure comprising a centerline, an outersurface of revolution and a plurality of tapering side walls defining aplurality of cavities in a geometric arrangement extending radially fromthe outer surface of revolution toward the centerline such that adjacentcavities of the plurality of cavities share a side wall or side wallportion therebetween, wherein each cavity being configured to receive anattitude control motor and the plurality of tapering side walls of eachcavity of at least some cavities includes: first cavity side wallstapering toward the centerline of the monolithic structure; secondcavity side walls tapering toward the centerline of the monolithicstructure; one or more of the second cavity side walls having a triangleshape between the outer surface of revolution and an inner surface ofthe monolithic structure; and each first cavity side wall having atrapezoidal shape between the outer surface of revolution and the innersurface of the monolithic structure, wherein the at least some cavitiesof the plurality of cavities of the monolithic structure exhibit anoctagon shape at the outer surface of revolution.
 2. The monolithicattitude control motor frame of claim 1, wherein remaining cavities ofthe plurality of cavities of the monolithic structure at the outersurface of revolution exhibit at least one of a square shape and arectangular shape.
 3. The monolithic attitude control motor frame ofclaim 1, wherein the inner surface defines a central passageway.
 4. Amonolithic attitude control motor frame, comprising: a monolithicstructure comprising: an outer surface of revolution and a plurality oftapering side walls defining a plurality of cavities, in a geometricarrangement, extending radially from the outer surface of revolution andtapering towards a centerline of the monolithic structure, such thatadjacent cavities of the plurality of cavities share a side wall or sidewall portion therebetween, each cavity of the plurality of cavitiesconfigured to receive an attitude control motor, and the plurality oftapering side walls of at least some cavities include: first cavity sidewalls that taper toward the centerline of the monolithic structure in arespective one cavity of the at least some cavities; second cavity sidewalls that taper toward the centerline of the monolithic structure inthe respective one cavity; the first cavity side walls and the secondcavity side walls are arranged in an alternating pattern; at least onesecond cavity side wall having a triangle shape between the outersurface of revolution and an inner surface of the monolithic structurein the respective one cavity; each first cavity side wall having atrapezoidal shape between the outer surface of revolution and the innersurface of the monolithic structure in the respective one cavity; andeach second cavity side wall being angled relative to those first cavityside walls being adjacent, wherein the at least some cavities exhibit anoctagonal shape at the outer surface of revolution.
 5. The monolithicattitude control motor frame of claim 4, wherein the at least somecavities comprise: at the inner surface, a square or rectangle, whereineach second cavity side wall forms a corner of the square or therectangle at the inner surface of the at least some cavities.
 6. Avehicle, comprising: a body; and a monolithic attitude control systemoperably associated with the body, the monolithic attitude controlsystem comprising: a plurality of attitude control motors, andmonolithic attitude control motor frame according to claim 4, whereinpressurization loads generated by operation of one of the plurality ofattitude control motors are transmitted to the monolithic frame.
 7. Amonolithic attitude control motor system, comprising: a monolithic framecomprising an outer surface of revolution and a plurality of side wallsdefining a plurality of cavities in a geometric arrangement extendingradially from the outer surface of revolution; and a plurality ofattitude control motors corresponding to the plurality of cavities, suchthat an attitude control motor of the plurality of attitude controlmotors is disposed in each cavity of the plurality of cavities; whereinthe plurality of side walls defines a first plurality of cavitiesexhibiting a first polygon shape at the outer surface of revolution andtapers to form a second polygon shape towards a centerline of themonolithic structure and a second plurality of cavities at the outersurface of revolution, different from the first plurality of cavities,and tapers towards the centerline of the monolithic structure; andwherein adjacent attitude control motors share a side wall or a portionof a side wall therebetween; and wherein pressurization loads generatedby operation of one of the plurality of attitude control motors aretransmitted to the monolithic frame; and wherein: the first polygonshape is an octagon; the first and second plurality of cavities areconfigured in the geometric arrangement at the outer surface ofrevolution of nested octagons and rectangles; and the second polygon ofthe first plurality of cavities exhibits at least one of a square shapeand a rectangular shape towards the centerline of the monolithicstructure; and wherein each cavity of the first plurality of cavitiescomprises: first cavity side walls of the plurality of side wallstapering toward the centerline of the monolithic structure; secondcavity side walls of the plurality of side walls tapering toward thecenterline of the monolithic structure; at least one second cavity sidewall having a triangle shape between the outer surface of revolution andan inner surface of the monolithic structure to form at least one cornerof the second polygon towards the centerline; and each first cavity sidewall having a trapezoidal shape between the outer surface of revolutionand the inner surface of the monolithic structure.
 8. A monolithicattitude control motor system, comprising: a monolithic frame comprisingan outer surface of revolution and a plurality of side walls defining aplurality of cavities in a geometric arrangement extending radially fromthe outer surface of revolution; and a plurality of attitude controlmotors corresponding to the plurality of cavities, such that an attitudecontrol motor of the plurality of attitude control motors is disposed ineach cavity of the plurality of cavities; wherein the plurality of sidewalls defines a first plurality of cavities exhibiting a first polygonshape at the outer surface of revolution and tapers to form a secondpolygon shape towards a centerline of the monolithic structure and asecond plurality of cavities at the outer surface of revolution,different from the first plurality of cavities, and tapers towards thecenterline of the monolithic structure; and wherein adjacent attitudecontrol motors share a side wall or a portion of a side walltherebetween; and wherein pressurization loads generated by operation ofone of the plurality of attitude control motors are transmitted to themonolithic frame; and wherein: the first polygon shape is an octagon;the first and second plurality of cavities are configured in thegeometric arrangement at the outer surface of revolution of nestedoctagons and rectangles; and the second polygon of the first pluralityof cavities exhibits at least one of a square shape and a rectangularshape towards the centerline of the monolithic structure; and whereineach cavity of the first plurality of cavities comprises: first cavityside walls of the plurality of side walls tapering toward the centerlineof the monolithic structure; second cavity side walls of the pluralityof side walls tapering toward the centerline of the monolithicstructure; the first cavity side walls and the second cavity side wallsare arranged in an alternating pattern; each first cavity side wallhaving a trapezoidal shape between the outer surface of revolution andan inner surface of the monolithic structure; and each second cavityside wall having a triangle shape between the outer surface ofrevolution and the inner surface of the monolithic structure and beingangled relative to adjacent first cavity side walls to form corners ofthe second polygon.
 9. A vehicle, comprising: a body; and a monolithicattitude control system operably associated with the body, themonolithic attitude control system comprising: a monolithic framecomprising an outer surface of revolution and a plurality of side wallsdefining a plurality of cavities in a geometric pattern extendingradially from the outer surface of revolution; and a plurality ofattitude control motors corresponding to the plurality of cavities, suchthat an attitude control motor of the plurality of attitude controlmotors is disposed in each cavity of the plurality of cavities; whereinadjacent attitude control motors share a side wall or a portion of aside wall therebetween; wherein the plurality of side walls defines afirst plurality of cavities exhibiting a first polygon shape at theouter surface of revolution and tapers to form a second polygon shapetowards a centerline of the monolithic structure and a second pluralityof cavities at the outer surface of revolution, different from the firstplurality of cavities, and tapers towards the centerline of themonolithic structure; and wherein pressurization loads generated byoperation of one of the plurality of attitude control motors aretransmitted to the monolithic frame and wherein: the first polygon shapeis an octagon; the first and second plurality of cavities are configuredin the geometric pattern at the outer surface of revolution of nestedoctagons and rectangles; and the second polygon of the first pluralityof cavities exhibits at least one of a square shape and a rectangularshape towards the centerline of the monolithic structure, wherein eachcavity of the first plurality of cavities comprises: first cavity sidewalls of the plurality of side walls tapering toward the centerline ofthe monolithic structure; second cavity side walls of the plurality ofside walls tapering toward the centerline of the monolithic structure;at least one second cavity side wall having a triangle shape between theouter surface of revolution and an inner surface of the monolithicstructure to form at least one corner of the second polygon; and eachfirst cavity side wall having a trapezoidal shape between the outersurface of revolution and the inner surface of the monolithic structure.10. A vehicle, comprising: a body; and a monolithic attitude controlsystem operably associated with the body, the monolithic attitudecontrol system comprising: a monolithic frame comprising an outersurface of revolution and a plurality of side walls defining a pluralityof cavities in a geometric pattern extending radially from the outersurface of revolution; and a plurality of attitude control motorscorresponding to the plurality of cavities, such that an attitudecontrol motor of the plurality of attitude control motors is disposed ineach cavity of the plurality of cavities; wherein adjacent attitudecontrol motors share a side wall or a portion of a side walltherebetween; wherein the plurality of side walls defines a firstplurality of cavities exhibiting a first polygon shape at the outersurface of revolution and tapers to form a second polygon shape towardsa centerline of the monolithic structure and a second plurality ofcavities at the outer surface of revolution, different from the firstplurality of cavities, and tapers towards the centerline of themonolithic structure; and wherein pressurization loads generated byoperation of one of the plurality of attitude control motors aretransmitted to the monolithic frame and wherein: the first polygon shapeis an octagon; the first and second plurality of cavities are configuredin the geometric pattern at the outer surface of revolution of nestedoctagons and rectangles; and the second polygon of the first pluralityof cavities exhibits at least one of a square shape and a rectangularshape towards the centerline of the monolithic structure; and whereineach cavity of the first plurality of cavities comprises: first cavityside walls of the plurality of side walls tapering toward the centerlineof the monolithic structure; second cavity side walls of the pluralityof side walls tapering toward the centerline of the monolithicstructure; the first cavity side walls and the second cavity side wallsare arranged in an alternating pattern; each first cavity side wallhaving a trapezoidal shape between the outer surface of revolution andan inner surface of the monolithic structure; and each second cavityside walls having a triangle shape between the outer surface ofrevolution and the inner surface of the monolithic structure and beingangled relative to adjacent first cavity side walls to form corners ofthe second polygon at the inner surface.